Rack control module

ABSTRACT

A rack control module including a pair of mounting braces for mounting the RCM on a handle of a power supply unit (PSU). The PSU may be mounted on a server rack. The RCM also includes a latch disposed in proximity to the pair of mounting brace. Upon mounting the RCM on the handle of the PSU, the latch locks the RCM in an engaged position with the handle of the PSU.

BACKGROUND

In a typical server rack, multiple hardware devices, such as a server, apower supply unit (PSU), a plurality of data storage devices, and aplurality of network elements are mounted. In such a server rack, thePSU is mounted in a power supply chassis specifically designed toreceive and mount the PSU. The PSU is removably secured with the powersupply chassis using a retention mechanism, such as a spring loadedlever and a latch. The PSU is electrically connected with a powerdistribution board (PDB) in the power supply chassis. The PDBdistributes power from the PSU to the server though a power managementdevice. A rack connector module (RCM) is coupled to the PDB and thepower management device for supporting power management functions of thepower management device.

BRIEF DESCRIPTION OF FIGURES

The detailed description is provided with reference to the accompanyingfigures. In the figures, the left-most digit(s) of a reference numberidentifies the figure in which the reference number first appears. Thesame numbers are used throughout the figures to reference like featuresand components.

FIGS. 1a and 1b schematically illustrate an example rack control module(RCM), in accordance with an example of the present subject matter.

FIG. 2 schematically illustrates the example RCM mounted on a powersupply unit (PSU), in accordance with an example of the present subjectmatter.

FIGS. 3a and 3b schematically illustrate the example RCM mounted on apower supply chassis, in accordance with an example of the presentsubject matter.

FIG. 4 schematically illustrates an example portion of a server rackincluding the power supply chassis, the PSU, and the RCM, in accordancewith an example of the present subject matter.

DETAILED DESCRIPTION

A rack control module (RCM) for supporting power distribution from apower supply unit (PSU) in a server rack is described herein. In theserver rack, a plurality of hardware devices, such as a server, the PSU,data storage devices, and network elements are stacked together tominimize floor space and to simplify cable connections between suchhardware devices. The server rack includes multiple chassis designedspecifically for mounting the hardware devices in the server rack. Onesuch chassis is a power supply chassis for mounting the PSU and a powerdistribution board (PDB) adjacent to the PSU in the server rack. The PDBis electrically connected with the PSU for distributing power to thehardware devices.

Generally, to manage power distribution to the server, a powermanagement device is connected with the server and the PDB. The powermanagement device performs power management functions, such as serverlevel power on and off, server power metering, dynamic power capping,and asset management capabilities to enable a user to control powerdistribution to the server. An example of such a power management deviceincludes an SL Advanced Power Manager (SLAPM) which is a compact powermanagement hardware device generally used with server racks. The PDB isconnected to the power management device through the RCM which supportspower management functions of the power management device.

The RCM is an L-shaped member which is securely attached to a side walland a base wall of the power supply chassis using a securing mechanism,such as screws. The RCM is securely attached to the power supply chassisafter mounting the PSU and a redundant PSU in the power supply chassis.The RCM includes an internal RCM connector which is electricallyconnected to with PDB in the power supply chassis through a ribboncable. The RCM further includes an external RCM connector which iselectrically connected with the internal RCM connector. The external RCMconnector is further electrically connected with the SLAPM throughanother ribbon cable. Thus, an electrical path is defined between thePDB and the SLAPM by the ribbon cables connected by the internal RCMconnector and the external RCM connector of the RCM.

However, as the RCM is securely attached to the side wall and the basewall of the power supply chassis, a PSU of higher power having a lengthlonger than the base wall of the power supply chassis cannot be mountedin the power supply chassis. Further, the ribbon cable connecting theRCM and the PDB is disposed on the base wall of the power supplychassis. As such, during insertion or removal of the PSU from the powersupply chassis, the ribbon cable may crumple making it susceptible todamage. In some cases, due to the crumpling, the ribbon cable may getsevered thereby resulting in either poor electrical connection or a lossof electrical connection. In some cases, the ribbon cable may further beprotected by way of a plastic cover that encloses the ribbon cable. Insuch a case, due to the crumpling, the plastic cover on the ribbon cablemay erode to a point where the wires inside the ribbon cable becomeexposed, which may result in short-circuiting of the ribbon cable.

When the ribbon cable is soldered to the internal RCM connector of theRCM, in case of damage, the entire ribbon cable along with the RCM wouldbe replaced. Also, the RCM is to be removed for insertion or removal ofa redundant PSU as a handle of the redundant PSU is blocked by the RCMwhich is securely attached to the side wall of the power supply chassis.As such, the process of insertion or removal of the redundant PSUbecomes time consuming. Additionally, due to lack of a provision forsafe keeping of the RCM removed during removal of the PSU, chances ofaccidental damage or loss of the RCM is considerably increased.

A rack control module (RCM) for supporting power distribution from apower supply unit (PSU) in a server rack is described. As per oneexample, the RCM as described may ease insertion or removal of the PSU.The server rack is used for mounting together a plurality of hardwaredevices, such as a server, the PSU, a plurality of data storage devices,and a plurality of network elements. As such, the amount of floor spacemay be reduced, and cable connections between such hardware devices maybe minimized.

As mentioned previously, the server rack may include a plurality ofchassis specifically designed for mounting different hardware devices inthe server rack. Examples of such chassis include power supply chassis,fan chassis, data storage chassis, server chassis, and so on. The powersupply chassis is designed specifically for mounting the PSU in theserver rack. The PSU includes power supply circuitry which convertsalternating current (AC) power obtained from an AC mains switch throughan AC power cable to a direct current (DC) power suitable for use by thehardware devices. The DC power from the PSU is then distributed by apower distribution board (PDB), mounted in the power supply chassisalong with the PSU, to the hardware devices.

For managing the power distribution from the PDB to the server, a powermanagement device is connected with the server and the PDB. The powermanagement device is mounted on the server rack in the power supplychassis along with the PDB and the PSU. The power management deviceprovides functions, such as server level power on and off, server powermetering, dynamic power capping, and asset management capabilities so asto enable a user to better control power distribution to the server.

Typically, the PSU and the PDB are mounted in the power supply chassissuch that the PSU and the PDB are adjacent to each other. In an example,the PSU may be mounted on a front side of the power supply chassis andthe PDB may be mounted on a rear side of the power supply chassis. Uponmounting, the PDB and the PSU are removably secured to a base wall ofthe power supply chassis. The PDB may be removably secured to the basewall of power supply chassis using securing mechanism, such as screws.The PSU may be removably secured to a side wall of power supply chassisusing retention mechanism, such as a spring loaded lever and a latch. Inan example, the retention mechanism may be provided on the PSU such thatthe PSU is removably secured with the side wall of the power supplychassis. The RCM, according to an example of the present subject matter,may then be mounted on a handle of the PSU such that the RCM engageswith the handle of the PSU.

In one example, the RCM includes a pair of mounting braces for mountingthe RCM onto the handle of the PSU. The pair of mounting braces maycompliment the shape of the handle of the PSU. In another example, theRCM may be shaped such that the pair of mounting braces may easilyengage with the handle of the PSU. The RCM may include a latch forlocking the RCM with the handle of the PSU once the pair of mountingbraces have engaged with the handle of the PSU. Once mounted andengaged, the latch may lock the RCM in an engaged position with thehandle of the PSU.

In one example, the RCM further includes an internal flexible printedcircuit (FPC) connector which is fixedly coupled to the RCM. In oneexample, the internal FPC connector may be selected depending on a sizeof the RCM. The internal FPC connector is further detachably coupledwith one end of a flat flexible cable (FFC). Another end of the FFC iscoupled to the PDB in the power supply chassis such that the FFCprovides an electrical connection between the RCM and the PDB. The FFCis further affixed along a length of the FFC on a surface of the basewall of the power supply chassis by using an affixing member applied tothe surface of the base wall of the power supply chassis. As such, theFFC provides a mechanical connection between the RCM and the PDB inaddition to providing the electrical connection between the RCM and thePDB.

Further, the RCM may include a strap aperture on a rear side of side ofthe RCM. The strap aperture is located between the pair of mountingbraces such that when the RCM is mounted on the handle of the PSU, thestrap aperture exposes a portion of the handle of the PSU. The strapaperture may allow a harnessing member to be coupled to the handle ofthe PSU and the RCM. The harnessing member may be used for fastening aconnecting member with the strap aperture.

Furthermore, the RCM includes an external RCM connector operably coupledwith the internal FPC connector. In one example, the external RCMconnector and the internal FPC connector are electrically connected witheach other through a printed circuit board. The external RCM connectoris further coupled with the power management device through a serverconnecting mechanism. The server connecting mechanism is detachablycoupled with the external RCM connector and the power management device.Therefore, the RCM is coupled to the PDB and the power management devicefor supporting power management functions of the power management devicethrough an electrical path defined by the FFC and the server connectingmechanism coupled by the internal FPC connector and the external RCMconnector of the RCM.

Thus, the RCM according to the present subject matter eases the entireprocess of insertion or removal of the PSU as the RCM is mounted on thehandle of the PSU and is not attached to the power supply chassis. Assuch, a redundant PSU may be easily mounted on or dismounted from thePSU without necessitating dismounting of the RCM mounted on the handleof the PSU. Also, a PSU of any length may be used as the RCM now mountson the handle of the PSU and is not attached to the power supplychassis. In an example, a PSU of higher power and having a length longerthan the base wall of the power supply may be used as the RCM easilymounts on the handle of the PSU of higher power.

Further, the RCM is detachably coupled with the FFC affixed on thesurface of the base wall of the power supply chassis. The affixing ofthe FFC on the surface of the power supply chassis provides themechanical connection between the RCM and the power supply chassis.Thus, when the latch is pressed to release the RCM from the engagedposition with the handle of the PSU, the RCM may be left coupled to thepower supply chassis through the FFC. Therefore, chances of accidentalloss or damage to the removed RCM are considerably reduced after the RCMis dismounted from the handle of the PSU.

Furthermore, the affixing of the FFC to the power supply chassisprevents the FFC from being crumpled during insertion or removal of thePSU. As such, the chances of damage to the FFC are considerably reduced.Also, as the FFC is detachably coupled with the internal FPC connector,the RCM or the FFC may be easily replaced. For example, if the RCM isdamaged, the RCM is detached from the FFC and is replaced withoutnecessitating a replacement of the FFC along with the RCM.

The manner in which the RCM is implemented shall be explained in detailwith respect to FIGS. 1 to 4. While aspects of the described RCM may beimplemented in any number of different structures using differentmaterials, the embodiments are described in the context of the followingexample RCM.

It should be noted that the description and figures merely illustratethe principles of the present subject matter. It will thus beappreciated that various arrangements that embody the principles of thepresent subject matter, although not explicitly described or shownherein, may be devised from the description and are included within itsscope. Moreover, all statements herein reciting principles, aspects, andembodiments of the present subject matter, as well as specific examplesthereof, are intended to encompass equivalents thereof.

FIG. 1a schematically illustrates an example of a rack control module(RCM) 100, in accordance with one example of the present subject matter.The RCM 100 may include a pair of mounting braces 102 for mounting theRCM 100 on a handle of a power supply unit (PSU) (not shown in thefigure). In an example, the pair of mounting braces 102 compliments theshape of handle of the PSU such that the pair of mounting braces 102easily engage with the handle of the PSU, upon mounting the RCM 100 ontothe handle of the PSU. The handle of the PSU may have different shapesaccording to industry standards or proprietary designs specified forsuch handles of the PSU. In an example, the pair of mounting braces 102may compliment the shape of the handle of the PSU according to thedifferent shapes of the handle. The RCM 100 may also include a latch 104for locking the RCM 100 with the handle of the PSU. After the pair ofmounting braces 102 are mounted and engaged with the handle of the PSU,the latch 104 may lock the RCM 100 in an engaged position with thehandle of the PSU

FIG. 1b schematically illustrates the example RCM 100 including variouscomponents for distributing power to a server from the PSU, inaccordance with one example of the present subject matter. Besides thepair of mounting braces 102 and the latch 104, the RCM 100 may furtherinclude an internal flexible printed circuit (FPC) connector 106. Theinternal FPC connector 106 provides a connection between a powerdistribution board (PDB) and the RCM 100 (not shown in figure) so as toreceive power from the PSU coupled with the PDB. The internal FPCconnector 106 is located beneath the pair of mounting braces 102.

It may be understood that the internal FPC connector 106 is anintegrated circuit (IC) socket mountable on a printed circuit board. Theinternal FPC connector 106 provides a mechanical and electricalconnection between a cable connected to the internal FPC connector 106and the printed circuit board. The internal FPC connector 106 may beeither a zero insertion force (ZIF) type socket or a non-ZIF typesocket. In an example, different sized internal FPC connector 106 may beselected depending upon a size of the RCM 100 that may easily allow theRCM 100 to mount on the handle of the PSU.

The RCM 100 may also include an external RCM connector 108 between thepair of mounting braces 102 on a lower rear side of the RCM 100. It maybe understood that the external RCM connector 108 is a socket mountableon a printed circuit board. The external RCM connector 108 provides amechanical and electrical connection between a cable connected with theexternal RCM connector 108 and the printed circuit board. In an example,the external RCM connector 108 may be an insulation-displacementconnector capable of coupling with a ribbon cable and providing anelectrical connection between the ribbon cable and a printed circuitboard.

Further, the internal FPC connector 106 and the external RCM connector108 are operably connected with each other. In one example, the internalFPC connector 106 and the external RCM connector 108 are electricallyconnected with each other through a RCM board 110. The RCM board 110 isa printed circuit board providing an electrical connection between theinternal FPC connector 106 and the external RCM connector 108. In suchexample, the internal FPC connector 106 and the external RCM connector108 may be mounted on the RCM board 110. The RCM board 110 may befixedly secured inside the RCM 100. Through the electrical connectionbetween the internal FPC connector 106 and the external RCM connector108, the RCM 100 supports the power management functions of a powermanagement device to enable a user to better control power distributionto the server.

Further, the RCM 100 may include a strap aperture 112 disposed betweenthe pair of mounting braces 102 on an upper rear side of the RCM 100.The strap aperture 112 exposes a portion of the handle of the PSU afterthe RCM 100 is mounted on the handle of the PSU. Additionally, a label114 may be coupled with the RCM 100 in between the pair of mountingbraces 102 through the strap aperture 112. The label 114 may includeinstructions about using the RCM 100 in a proper manner. The label 114may also provide warnings and any other appropriate information inrelation to use of the RCM 100. In an example, the label 114 may beaffixed on the RCM 100 using an adhesive.

FIG. 2 schematically illustrates a PSU 200 with the RCM 100, inaccordance with one example of the present subject matter. The PSU 200,as may be understood, includes power supply circuitry (not shown in thefigure) which converts alternating current (AC) power to a directcurrent (DC) power suitable for use by hardware devices, such as aserver (not shown in the figure). The PSU 200 further includes a handle202 for facilitating insertion and removal of the PSU 200 in a powersupply chassis (not shown in the figure). The PSU 200 also includes aretention mechanism 204 for removably securing the PSU 200 in the powersupply chassis. Upon insertion of the PSU 200 in the power supplychassis, the PSU 200 is removably secured to a side wall of the powersupply chassis through the retention mechanism 204. Examples of theretention mechanism 204 include a latch and a spring loaded lever. In anexample, the retention mechanism 204 may be provided on the PSU 200.

As described earlier, upon insertion of the PSU 200 in the power supplychassis, the RCM 100 may be mounted on the handle 202 of the PSU 200 bymounting the pair of mounting braces 102 on the handle 202 of the PSU200. The pair of mounting braces 102 compliments the shape of the handle202 of the PSU 200 thereby allowing the RCM 100 to engage easily withthe handle 202 of the PSU 200. Upon mounting and engaging the pair ofmounting braces 102 with the handle 202 of the PSU 200, the latch 104locks the RCM 100 in an engaged position with the handle 202 of the PSU200. The latch 104 may be further pressed to release the RCM 100 fromthe engaged position with the handle 202 of the PSU 200.

FIG. 3a schematically illustrates a power supply chassis 300 with theRCM 100, in accordance with one example of the present subject matter.The power supply chassis 300 is a specifically designed chassis in aserver rack for mounting a PSU (not shown in the figure) and a powerdistribution board (PDB) 302 in the server rack. In one example, twoPSUs may be mounted in the power supply chassis 300 such that one of thePSUs is used as a redundant power supply unit. As described earlier, thePSU converts AC power obtained from an AC mains switch through an ACpower cable to DC power suitable for use by hardware devices, such as aserver. The PDB 302 is electrically coupled with the PSU fordistributing the DC power to the hardware devices.

The PDB 302 and the PSU are mounted on a base wall of the power supplychassis 300 such that the PDB 302 and the PSU are adjacent to each otherfor facilitating electrical connection between the PDB 302 and the PSU.In an example, the PDB 302 may be mounted on a rear side of the powersupply chassis 300 and the PSU may be mounted on a front side of thepower supply chassis 300. Upon mounting, the PDB 302 and the PSU areremovably secured to the base wall of the power supply chassis 300. ThePDB 302 may be removably secured to the base wall of the power supplychassis 300 using securing mechanism, such as screws. The PDB 302 andthe PSU may be coupled with electrical cables for facilitating theelectrical connection between the PDB 302 and the PSU.

As described earlier, to better manage the power distribution from thePDB 302 to the server, a power management device (not shown in thefigure) is connected with the server and the PDB 302. The powermanagement device is mounted in the power supply chassis 300 along withthe PDB 302 and the PSU. The power management device provides powermanagement functions to enable a user to better control powerdistribution to the server. Such power management functions may include,for example, server level power on and off, server power metering,dynamic power capping, and asset management capabilities. An example ofone such power management device includes an SL Advanced Power Manager.

In an example, the PDB 302 may distribute power from the PSU to a serverin the server rack through the power management device. The PDB 302 andthe power management device are coupled through the RCM 100. The PDB 302includes an RCM connector 304 for coupling with the RCM 100. In anexample, the RCM connector 304 may be an insulation-displacementconnector. The RCM connector 304 is coupled with one end of a flatflexible cable (FFC) 306, as shown in FIG. 3b . The FFC 306 is coupledwith the RCM connector 304 on the one end through a connector capable ofcoupling with the RCM connector 304. In an example, the connector on oneend of the FFC 306 may be an insulation-displacement connector.

The FFC 306 may be further affixed on a surface of the base wall of thepower supply chassis 300 along a length of the FFC 306 by using anaffixing member applied to the surface of the base wall of the powersupply chassis. In an example, the affixing member may be an adhesivelayer applied to the surface of the base wall of the power supplychassis 300. Examples of such adhesive layer include double side plastictapes and adhesive transfer tapes. In some cases, the FFC 306 may beaffixed to the adhesive layer after the adhesive layer is applied to thesurface of the base wall of the power supply chassis along the length ofthe FFC 306. In another example, the affixing member may be a fasteningmember applied to the surface of the base wall of the power supplychassis 300. One example of such a fastening member includes Velcro. Insuch an example, the FFC 306 may be affixed to the fastening memberafter the fastening member is applied to the surface of the base wall ofthe power supply chassis 300 along the length of the FFC 306. Theaffixing of the FFC 306 with the base wall of the power supply chassis300 reduces chance of damage to the FFC 306 during insertion and removalof the PSU as the FFC 306 is prevented from being crumpled or otherwisedisplaced during insertion and removal of the PSU.

Further, another end of the FFC 306 is detachably coupled with theinternal FPC connector 106 in the RCM 100. In one example, another endof the FFC 306 may include either a zero insertion force (ZIF) ornon-ZIF electrical connector capable of coupling with the internal FPCconnector 106. Thus, the FFC 306 provides a mechanical and an electricalconnection between the RCM 100 and the PDB 302 upon coupling with theinternal FPC connector 106 in the RCM 100 and with the RCM connector 304in the PDB 302. Accordingly, when the latch 104 is pressed to releasethe RCM 100 from the engaged position with the handle of the PSU, theRCM 100 may be left coupled to the power supply chassis 300 through theFFC 306. Therefore, chances of accidental loss or damage to the RCM 100are considerably reduced after the RCM 100 is dismounted from the handleof the PSU. Also, the detachable coupling of the FFC 306 with the RCM100 enables individual and easy replacement of either the FFC 306 or theRCM 100 thereby eliminating replacement of both the FFC 306 and the RCM100. For example, if the RCM 100 is damaged, the RCM 100 is detachedfrom the FFC 306 and replaced without necessitating the replacement ofthe FFC 306.

As described earlier, the PDB 302 distributes power to the powermanagement device by the RCM 100 through the electrical connectionprovided by the FFC 306. The power from the PDB 302 is received at theinternal FPC connector 106 through the FFC 306. Thereafter, as theexternal RCM connector 108 and the internal FPC connector 106 areelectrically connected with each other, the power from the internal FPCconnector 106 is received at the external RCM connector 108 in the RCM100. The external RCM connector 108 is further coupled with the powermanagement device through a server connecting mechanism (not shown inthe figure). Examples of the server connecting mechanism include ribboncables. The server connecting mechanism is detachably coupled with theexternal RCM connector 108 and the power management device. Thus, thepower from the PDB 302 is thus distributed to the power managementdevice through an electrical path defined by the FFC 306 and the serverconnecting mechanism coupled with the internal FPC connector 106 and theexternal RCM connector 108 in the RCM 100.

FIG. 4 schematically illustrates a portion of a server rack 400including the power supply chassis 300, the PSU 200, and the RCM 100, inaccordance with one example of the present subject matter. In the serverrack 400, a plurality of hardware devices, such as a server, a powersupply unit (PSU), a plurality of data storage devices, and a pluralityof network elements are mounted together. Such mounting of the hardwaredevices saves floor space and minimizes long cable connections betweenthe hardware devices. The server rack 400 may include the power supplychassis 300 for mounting the PSU 200 and the PDB 302, a fan chassis 402for mounting a cooling fan, and other chassis for mounting otherhardware devices, such as data storage devices and network elements.These chassis are specifically designed for mounting the hardwaredevices in the server rack 400.

As described earlier, upon insertion of the PDB 302 into the powersupply chassis 300, the FFC 306 is coupled with the RCM connector 304 ofthe PDB 302 and is affixed to the surface of the base wall of the powersupply chassis 300 along the length of the FFC 306. Thereafter, the PSU200 is inserted into the power supply chassis 300 such that the PSU 200is adjacent to the PDB 302. In an example, a redundant PSU may also bemounted on top of the PSU 200 in the power supply chassis 300. In suchexample, the redundant PSU may be electrically connected with the PDB302 so that power may be provided to the PDB 302 without interruption inan event of failure of the PSU 200.

Upon inserting and securing the PSU 200 in the power supply chassis 300,the FFC 306 may be detachably coupled with the internal FPC connector106 of the RCM. Thereafter, the RCM 100 is mounted on the handle 202 ofthe PSU 200 through the pair of mounting braces 102. The pair ofmounting braces 102 of the RCM 100 compliment the shape of the handle202 of the PSU 200 and as such easily engage the RCM 100 with the handle202 of the PSU 200. Upon mounting and engaging, the latch 104 of the RCM100 locks the RCM 100 in an engaged position with the handle 202 of thePSU 200. Thus, the RCM 100 is securely locked with the handle 202 of thePSU 200. Further, the external RCM connector 108 of the RCM 100 may bedetachably coupled with the power management device through the serverconnecting mechanism. Thus, the electrical path is defined to distributethe power from the PDB 302 to the power management device through theRCM 100.

Furthermore, a harnessing member (not shown in the figure) may becoupled to the handle 202 of the PSU 200 and the RCM 100 through thestrap aperture 112. Examples of the harnessing member include Velcroretention straps and cable ties. The harnessing member may be used forsecuring connecting member with the RCM 100 for preventing accidentaldamage to the connecting member. Examples of the connecting memberinclude electrical cables, such as power cables and network cables andcommunicative cables, such as ribbon cables and bus cables. In anexample, a Velcro retention strap may be wrapped around the handle 202of the PSU 200 through the strap aperture 112. In such example, theVelcro retention strap may be used for securing and retaining an ACpower cable connected to the PSU 200 for preventing accidentalunplugging of the AC power cable.

Although the examples of RCM are described in language specific tostructural features, it is to be understood that the appended claims arenot necessarily limited to the specific features described. Rather, thespecific features and methods are disclosed as examples of the RCM.

We claim:
 1. A rack control module (RCM) comprising: a pair of mountingbraces for mounting the RCM on a handle of a power supply unit (PSU),wherein the PSU is mountable on a server rack; and a latch for lockingthe RCM in an engaged position with the handle of the PSU, the latchbeing disposed in proximity to the pair of mounting braces.
 2. The RCMas claimed in claim 1 further comprising an internal flexible printedcircuit (FPC) connector fixedly coupled to the RCM, wherein the internalFPC connector is to detachably couple with one end of a flat flexiblecable (FFC).
 3. The RCM as claimed in claim 2, wherein the FFC isaffixed using an affixing member applied on a surface of the server rackalong a length of the FFC.
 4. The RCM as claimed in claim 3, wherein theaffixing member is an adhesive layer applied on the surface of theserver rack along the length of the FFC.
 5. The RCM as claimed in claim3, wherein the affixing member is a fastening member applied on thesurface of the server rack along the length of the FFC.
 6. The RCM asclaimed in claim 1 further comprising a strap aperture on an upper rearside of the RCM and disposed between the pair of mounting bracesexposing the handle of the PSU, wherein a harnessing member is coupledto the handle of the PSU through the strap aperture, the harnessingmember fastening a connecting member with the strap aperture.
 7. The RCMas claimed in claim 1 further comprising an external RCM connector on arear side of the RCM and disposed at distal end of the pair of mountingbraces, the external RCM connector being detachably coupled with aserver connecting mechanism, the server connecting mechanism couplingthe external RCM connector with a power management device mounted on theserver rack, wherein the external RCM connector is operably coupled tothe internal FPC connector.
 8. A server rack comprising: a power supplychassis; at least one PSU enclosed in the power supply chassis; and arack control module (RCM) mounted on the at least one PSU in the powersupply chassis, the RCM comprising: a pair of mounting braces formounting the RCM on a handle of the at least one PSU; and a latch forlocking the RCM in an engaged position with the handle of the at leastone PSU, the latch being disposed in proximity to the pair of mountingbraces.
 9. The server rack as claimed in claim 8 further comprising aninternal flexible printed circuit (FPC) connector fixedly coupled to theRCM, wherein the internal FPC connector is to detachably couple with oneend of a flat flexible cable (FFC).
 10. The server rack as claimed inclaim 9, wherein an affixing member applied on a surface of the powersupply chassis along a length of the FFC is used for affixing the FFC onthe surface of the power supply chassis.
 11. The server rack as claimedin claim 10, wherein the affixing member is an adhesive layer applied onthe surface of the power supply chassis along the length of the FFC. 12.The server rack as claimed in claim 10, wherein the affixing member is afastening member applied on the surface of the power supply chassisalong the length of the FFC.
 13. The server rack as claimed in claim 8further comprising a power distribution board (PDB) enclosed in thepower supply chassis, the PDB operably coupled to the at least one PSU,wherein a RCM connector is fixedly coupled to the PDB and is detachablycoupled with another end of the FFC.
 14. The server rack as claimed inclaim 8, wherein the RCM further comprises an external RCM connector ona rear side of the RCM and disposed at distal end of the pair ofmounting braces, the external RCM connector operably coupled to theinternal FPC connector and detachably coupled to a server connectingmechanism, the server connecting mechanism coupling the RCM and a powermanagement device mounted on the server rack.
 15. The server rack asclaimed in claim 8, wherein the RCM further comprises a strap apertureon an upper rear side of the RCM and disposed in proximity to the pairof mounting braces exposing the handle of the at least one PSU, whereinthe handle of the at least one PSU is coupled to a harnessing memberthrough the strap aperture, the harnessing member fastening a connectingmember with the strap aperture.